Humerus Fractures Overview (2024)

Continuing Education Activity

Humerus fractures account for 4 to 6 percent of all fractures in young patients and 1 to 3 percent of all fractures in elderly patients. In young men, these fractures are usually a result of high-energy trauma while in the older population, these fractures are typically seen in women after a ground-level fall. Interestingly, humerus shaft fractures in polytrauma patients are independent predictors of intra-abdominal injury, long bone, and hand fractures. Typically, these injuries cause temporary disability in the younger population whereas permanent disability can be seen in the elderly population. This activity describes the evaluation, diagnosis, and management of humerus fractures and stresses the role of team-based interprofessional care for affected patients.

Objectives:

• Describe the anatomy pertinent to humerus fractures.

• Outline the complications of humerus fractures.

• Summarize the treatment considerations for humerus fractures.

• Explain interprofessional team strategies for enhancing care coordination and communication to advance the evaluation and management of humerus fractures and improve patient outcomes.

Access free multiple choice questions on this topic.

Introduction

The proximal humerus has two necks. The anatomic neck is the old epiphyseal plate, and the surgical neck is the metaphyseal area below the humeral head. The blood supply is the anterior and posterior humeral circumflex artery with the axillary nerve as the major nerve of this region. The humeral shaft is a cylindrical bone that gradually becomes triangular distally. This bone serves as an insertion site for the pectoralis major, deltoid, and coracobrachialis and is the site of origin for the brachialis, triceps, andbrachioradialis. The radial nerve is the major nerve of the humerus shaft which is seen in the spiral groove and is approximately 14 cm from the lateral epicondyle and 20 cm from the medial epicondyle. The major nerves of the distal humerus are the ulnar nerve and radial nerve. Distal humerus fractures comprise the supracondylar fractures, single condyle fractures, bi-column fractures and coronal shear fractures.Treatment options include open reduction and internal fixation, closed reduction and percutaneous pinning, and intramedullary nailing or bracing.[1][2][3]

Etiology

Humerus fractures occur as a result of trauma or pathologic fractures often due to metastatic disease. When these fractures are due to trauma, they occur from both high- and low-energy trauma.[4]

Epidemiology

Proximal humerus and humerus fractures account for 4% to 6% and 1% to 3% of all fractures respectively in both youngand elderly patients. In young men, these fractures are usually a result of high-energy trauma while in the older population, this fracture is seen in women after a ground-level fall. Interestingly, humerus shaft fractures in polytrauma patients are independent predictors of intra-abdominal injury, long bone, andhand fractures. Typically, these injuries cause temporary disability in the younger population whereas permanent disability can be seen in the elderly.[5][6]

History and Physical

Common physical exam findings include erythema of the of the arm, inability to lift the arm due to pain, and holding onto the elbow of the injured arm for support. During the physical exam, neurovascular status pre- and postreduction is critical to identify any iatrogenic injury to neurovascular structures.In some instances, fracture reduction is necessary and is typically assisted by the influence of gravity with the arm in the anatomic position.

Evaluation

The recommended views for radiographic evaluationof the proximal humerus fracture include a true AP, scapular Y, and axillary. CT scan is performed for preoperative planning if there is intra-articular comminution or if the position of the head or greater tuberosity is uncertain. If a humerus shaft fracture is suspected, AP and lateral views including the joint below and above should be a part of the initial evaluation. With suspected distal humerus fractures, the recommended radiographic views include an AP and lateral of the humerus and elbow which should include the entire humerus and forearm.[7]

Treatment / Management

Nonoperative management with a sling and progressive rehabilitation of proximal humerus fractures isindicated in minimally displaced surgical neck fractures, greater tuberosity fractures displaced less than 5 millimeters, and patients who are not surgical candidates. Closed reduction and percutaneous pinningisindicated fortwo-part surgical neck fractures, 3-part and valgus-impacted four-part fractures with minimal metaphyseal comminution, and an intact medial calcar. Open reduction and internal fixation isindicated in greater tuberosity fractures displaced more than 5 millimeters and head-splitting fractures in young patients. Intramedullary rodding indications include surgical neck fractures or 3-part greater tuberosity fractures in younger patients and combined proximal humerus and humeral shaft fractures. Hemiarthroplasty is a viable option in anatomic fractures in elderly patients and fractures not amenable to open reduction and internal fixation. Total shoulder arthroplasty isindicated if the glenoid surface iscompromised, while reverse total shoulder arthroplasty isindicated in individuals in a nonfunctioning rotator cuff or elderly individuals with reconstructable tuberosities.[8][9][1]

Traditionally, the mainstay of treatment of humerus shaft fractures is nonoperative. Due to thenon-weight-bearingnature of the bone and the vast soft tissue envelope, slight deformity can be acceptable with favorable results. In most cases, nonoperative treatment consists of aSarmientobrace. An advantage of using this brace is that the joints above and below the fracture are mobile, minimizing joint stiffness. Another advantage isremovability of thebrace,allowingfor better axillary hygiene. Fracture alignment is maintained by the soft tissue envelope of the upper arm which has been described as the inner splint. Indications for nonoperative treatment includeacceptable alignmentless than 20degrees anterior angulation, less than 30 degrees varus, valgus angulation, and less than 3 centimeters shortening. Absolute contraindicationsincludesevere soft tissue injury or bone loss, vascular injury requiring repair and brachial plexus injury. Typically, a coaptation splint is first used for 3 to 4 weeks until the swelling resolves. Next, a functional brace is utilized extending from approximately 2.5 centimeters distal to the axilla to 2.5 centimeters proximal to the humeral condyles. Weekly radiographs are recommended for the first 3 weeks to ensure adequate reduction. After this period, radiographs can be taken every 3 to 4 weeks.

Open reduction and internal fixationare indicatedin open fractures, vascular injury requiring repair, brachial plexus injury, floating elbow (ipsilateral forearm fracture), and compartment syndrome. Other relative indicationsinclude polytrauma, bilateral humerus fractures, pathologic fractures, andburns or soft tissue injuryprecluding bracing. Benefits of this procedure include direct visualization of the fracture, anatomic fracture reduction, interfragmentary compression, identification of the radial nerve, and no violation of the adjacent joints. Disadvantages include the increased risk of soft tissue stripping, the riskof fracture at the end of the plate, and poor screw purchase in osteoporotic or comminuted bone. Dynamic compression plating is often the implant used when open reduction and internal fixation are performed, but locking platescan be helpful inosteoporotic bone. Minimally invasive plate fixation is another method that can be used but is not commonly performed. Some of the theoretical advantagesofthis methodincludeadecreased amount of soft tissue injury and stripping which increases the healing potential in the injured area.

Depending on the location of the fracture, different surgical approaches are used. The deltopectoral approach or lateral approach can be used for proximal humerus fractures. The anterolateral approach is used for proximal to middle third shaft fractures. In this approach, the radial nerve is identified between the brachialis and brachioradialis distally. The posterior approach to the humerus is utilized for distal to middle third shaft fractures. During the approach, the triceps can either be split or elevated with lateralparatricipitalexposure. The radial nerve is medial to the long and lateral heads of the triceps, while it is approximately 2 centimeters proximal to the deep head of the triceps and leaves the posterior compartment through the lateral intramuscular septum approximately 10centimetersproximal to theradiocapetellarjoint.

External fixation of the humerus shaft is not commonly performed but can be used asa method for stabilization in the unstable patient or open fractures with severe tissue loss.

Intramedullary nailing has comparable union rates and is another viable option for patients. Indications are pathologic fractures, segmental fractures, andcomminuted fractures. This method is less invasive and typically involves shorter operating time. Disadvantagesincludean increased incidence of shoulder dysfunction, pain at the entry site, and rotational deformity.

Treatment of distal humerus fractures includes cast immobilization for Milch type I fractures. Closed reduction and percutaneous pinning are performed in displaced Milch Type I fractures, and open reduction and internal fixation is performed in supracondylar fractures, intercondylar/bicolumnar fractures, and Milch Type II fractures. Total elbow arthroplasty is indicated in elderly patients with distal bicolumnar fractures.

Differential Diagnosis

• Elbow fracture

• Clavicle fractures

• Scapula fracture

• Shoulder dislocation in emergency management

Prognosis

Proximal humerus and shaft fractures have favorable outcomes with a high union rate and low infection rate after operative and nonoperative management. Distal humerus fractures have less favorable outcomes. Approximately 75% of patients regain elbow motion and strength with the goal of a range of motion to between 30 and 130 degrees.

Complications

Radial nerve palsy is a feared complication of humerus shaft fractures that can occur during the injury, open reduction, and internal fixation or intramedullary nailing. In closed fractures, this is often a result of neuropraxia, while in open fractures it is a result soneurogenesis. This complication is more common in third distal fractures as this is the location where the radial nerve is closest to the humerus. Inaclosed fracture, radial nerve palsy is not an indication for open reduction and internal fixation with nerve exploration. Most palsies return with notreatment in 3 to 6 months. If no return of function is seen at 3 to 4 months, an EMG should be performed. Surgical exploration is indicated in open fractures, a closed fracture with the failureof improvement over 3 to 6 months, and fibrillationsat 3 to 4 months on EMG.

Pearls and Other Issues

Proximal humerus fractures are classified based on the Neer classification as 2-, 3-, and 4-part fractures. These are classified asthe greater and lesser tuberosity, articular surface, and shaft displaced more than 1 cm or greater than 45 degrees. Distal humerus fractures comprise of supracondylar fractures, single condyle fractures, bicolumnar fractures, and coronal shear fractures. These fractures can be classified as supracondylar fractures and distal single-column fractures and subclassified using the Milch classification. Milch type I fractures are fractures through the lateral trochlear ridge compared to Milch type II fractures with the lateral trochlear ridge intact. The Jupiter classification is used to identify five articular fragments: (1) thecapitellum/lateral trochlea, (2) lateral epicondyle, (3) posterolateral epicondyle, (4) posterior trochlea, and (5)medial trochlea/epicondyle.With distal humerus fractures, if the elbow is flexed less than 90 degrees, a transcolumnar fracture is seen and a direct posterior injury results in an olecranon fracture compared to elbow flexion greater than 90 degrees with anintercondylar fracture.

Enhancing Healthcare Team Outcomes

Humerus fractures are relatively common in the elderly and in those who participate in intense physical sporting activities. The majority of patients with humerus fracture first present to the emergency department and hence the triage nurse and emergency room physician must be aware of the importance of prompt referral to an orthopedic surgeon. The outcomes for most patients with humerus fracture are good. Complete union can often take 6-10 weeks and even after recovery, some patients may exhibit a slight decrease in the shoulder range of motion. It is very important to follow up patients with humerus fracture to ensure that they are not developing the frozen shoulder; hence sometype ofexerciserehab program must be recommended.[2][10]

Review Questions

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References

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Hu B, Liu XW, Huang JJ. [Surgical treatment for distal humerus type C fractures]. Zhongguo Gu Shang. 2018 Oct 25;31(10):976-982. [PubMed: 30373356]

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Zarezadeh A, Mamelson K, Thomas WC, Schoch BS, Wright TW, King JJ. Outcomes of distal humerus fractures: What are we measuring? Orthop Traumatol Surg Res. 2018 Dec;104(8):1253-1258. [PubMed: 30352777]

3.

Verdano MA, Aliani D, Galavotti C, Maroun C, Vaienti E, Ceccarelli F. Grammont versus lateralizing reverse shoulder arthroplasty for proximal humerus fracture: functional and radiographic outcomes. Musculoskelet Surg. 2018 Oct;102(Suppl 1):57-65. [PubMed: 30343472]

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Martinez-Huedo MA, Jiménez-García R, Mora-Zamorano E, Hernández-Barrera V, Villanueva-Martinez M, Lopez-de-Andres A. Trends in incidence of proximal humerus fractures, surgical procedures and outcomes among elderly hospitalized patients with and without type 2 diabetes in Spain (2001-2013). BMC Musculoskelet Disord. 2017 Dec 11;18(1):522. [PMC free article: PMC5725839] [PubMed: 29228945]

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Haeberle HS, Navarro SM, Power EJ, Schickendantz MS, Farrow LD, Ramkumar PN. Prevalence and Epidemiology of Injuries Among Elite Cyclists in the Tour de France. Orthop J Sports Med. 2018 Sep;6(9):2325967118793392. [PMC free article: PMC6124184] [PubMed: 30202769]

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Willeumier JJ, van de Sande MAJ, van der Wal RJP, Dijkstra PDS. Trends in the surgical treatment of pathological fractures of the long bones: based on a questionnaire among members of the Dutch Orthopaedic Society and the European Musculo-Skeletal Oncology Society (EMSOS). Bone Joint J. 2018 Oct;100-B(10):1392-1398. [PubMed: 30295518]

7.

Carbone S, Mezzoprete R, Papalia M, Arceri V, Carbone A, Gumina S. Radiographic patterns of osteoporotic proximal humerus fractures. Eur J Radiol. 2018 Mar;100:43-48. [PubMed: 29496078]

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Grobet C, Marks M, Tecklenburg L, Audigé L. Application and measurement properties of EQ-5D to measure quality of life in patients with upper extremity orthopaedic disorders: a systematic literature review. Arch Orthop Trauma Surg. 2018 Jul;138(7):953-961. [PubMed: 29654354]

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Heggeness MH, Sanders JO, Murray J, Pezold R, Sevarino KS. Management of Pediatric Supracondylar Humerus Fractures. J Am Acad Orthop Surg. 2015 Oct;23(10):e49-51. [PubMed: 26320161]

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Disclosure: Basem Attum declares no relevant financial relationships with ineligible companies.

Disclosure: Johnathan Thompson declares no relevant financial relationships with ineligible companies.